Your search keyword '"Saharan dust"' showing total 860 results

1. Use of Low-Cost Sensors to Study Atmospheric Particulate Matter Concentrations: Limitations and Benefits Discussed through the Analysis of Three Case Studies in Palermo, Sicily.

Author

Brugnone, Filippo, Randazzo, Luciana, and Calabrese, Sergio

Subjects

*PARTICULATE matter, *METEOROLOGICAL stations, *AIR pollution, *MEASURING instruments, *DUST

Abstract

The paper discusses the results of the concentrations of atmospheric particulate matter, in the PM2.5 and PM10 fractions, acquired by two low-cost sensors. The research was carried out from 1 July 2023 to 30 June 2024, in Palermo, Sicily. The results obtained from two systems equipped with the same sensor model were compared. Excellent linear correlation was observed between the results, with differences in measurements falling within instrumental accuracy. Two instruments equipped with different sensors, models Novasense SDS011 and Plantower PMSA003, were placed at the same site. These were complemented by a weather station to measure meteorological parameters. Upon comparing the atmospheric particulate matter concentrations measured by the two instruments, it was observed that there was a good linear correlation for PM2.5 and a poor linear correlation for PM10. Additionally, the PMSA003 sensor appeared to consistently record higher concentrations than the SDS011 sensor. During periods influenced by natural sources and/or anthropogenic activities at the regional and/or local scale, i.e., the dispersal of Saharan sands, forest fires, and local events using fireworks, abnormal concentrations of atmospheric particulate matter were detected. Despite the inherent limitations in precision and accuracy, both low-cost instruments were able to identify periods with abnormal concentrations of atmospheric particulate matter, regardless of their source or type. [ABSTRACT FROM AUTHOR]

Published

2024

2. Analyzing Trends in Saharan Dust Concentration and Its Relation to Sargassum Blooms in the Eastern Caribbean.

Author

Hernández Ayala, José J. and Méndez-Tejeda, Rafael

Subjects

*OCEAN temperature, *MARINE ecology, *ENVIRONMENTAL monitoring, *SARGASSUM, *DUST

Abstract

This study investigates the temporal trends and correlations between Saharan dust mass concentration densities (DMCD) and Sargassum concentrations (SCT) in the tropical North Atlantic. Average DMCD data for June, July, and August from 1980 to 2022, alongside SCT data for the same months from 2012 to 2022, were analyzed using Mann–Kendall tests for trends and lagged regression models to assess whether higher Saharan dust levels correlate with Sargassum outbreaks in the region. A comprehensive analysis reveals a significant upward trend in Saharan dust quantities over the study period, with the summer months of June, July, and August exhibiting consistent increases. Notably, 2018 and 2020 recorded the highest mean DMCD levels, with June showing the most significant increasing trend, peaking in 2019. These findings are consistent with previous studies indicating a continuous elevation in Saharan dust concentrations in the tropical atmosphere of the North Atlantic. Simultaneously, Sargassum concentrations also show a notable increasing trend, particularly in 2018, which experienced both peak SCT and elevated DMCD levels. Mann–Kendall tests confirm statistically significant upward trends in both Saharan dust and Sargassum concentrations. Simple linear regression and lagged regression analyses reveal positive correlations between DMCD and SCT, highlighting a temporal component with stronger associations observed in July and the overall June–July–August (JJA) period. These results underscore the potential contribution of elevated Saharan dust concentrations to the recent surge in Sargassum outbreaks in the tropical North Atlantic. Furthermore, the results from forward stepwise regression (FSR) models indicate that DMCD and chlorophyll (CHLO) are the most critical predictors of SCT for the summer months, while sea surface temperature (SST) was not a significant predictor. These findings emphasize the importance of monitoring Saharan dust and chlorophyll trends in the Eastern Caribbean, as both factors are essential for improving Sargassum modeling and prediction in the region. This study provides valuable insights into the climatic factors influencing marine ecosystems and highlights the need for integrated environmental monitoring to manage the impacts on coastal economies. [ABSTRACT FROM AUTHOR]

Published

2024

3. Air Quality Assessment in Six Major Greek Cities with an Emphasis on the Athens Metropolitan Region.

Author

Dimitriou, Konstantinos and Mihalopoulos, Nikolaos

Subjects

*AIR quality indexes, *PARTICULATE matter, *AIR quality, *METROPOLIS, *BIOMASS burning, *AIR pollution, *AIR pollutants

Abstract

To assess the impact of air pollution on human health in multiple urban areas in Greece, hourly concentrations of common air pollutants (CO, NO2, O3, SO2, PM10, and PM2.5) from 11 monitoring stations in six major Greek cities (Athens, Thessaloniki, Patra, Volos, Ioannina, and Kozani), were used to implement the U.S. EPA's Air Quality Index (AQI) during a seven-year period (2016–2022). In Athens, the capital city of Greece, hourly PM10 and PM2.5 concentrations were also studied in relation to the prevailing wind patterns, while major PM10 episodes exceeding the official daily EU limit (50 μg/m3) were analyzed using the Potential Source Contribution Function (PSCF) in terms of the air mass origin. According to the AQI results, PM10 and PM2.5 were by far the most hazardous pollutants associated with moderate and unhealthy conditions in all the studied areas. In addition, in Athens, Thessaloniki, and Patra, where the benzene levels were also studied, a potential inhalation cancer risk (>1.0 × 10−6) was detected. In Athens, Saharan dust intrusions were associated with downgraded air quality, whilst regional transport and the accumulation of local emissions triggered increased PM10 and PM2.5 levels in traffic sites, especially during cold periods. Our study highlights the need for the development of early warning systems and emission abatement strategies for PM pollution in Greece. [ABSTRACT FROM AUTHOR]

Published

2024

4. Large-Scale Network-Based Observations of a Saharan Dust Event across the European Continent in Spring 2022.

Author

Papanikolaou, Christina-Anna, Papayannis, Alexandros, Gidarakou, Marilena, Abdullaev, Sabur F., Ajtai, Nicolae, Baars, Holger, Balis, Dimitris, Bortoli, Daniele, Bravo-Aranda, Juan Antonio, Collaud-Coen, Martine, de Rosa, Benedetto, Dionisi, Davide, Eleftheratos, Kostas, Engelmann, Ronny, Floutsi, Athena A., Abril-Gago, Jesús, Goloub, Philippe, Giuliano, Giovanni, Gumà-Claramunt, Pilar, and Hofer, Julian

Subjects

*AEROSOLS, *AIR masses, *CENTER of mass, *HUMIDITY, *SPATIAL variation, *DUST

Abstract

Between 14 March and 21 April 2022, an extensive investigation of an extraordinary Saharan dust intrusion over Europe was performed based on lidar measurements obtained by the European Aerosol Research Lidar Network (EARLINET). The dust episode was divided into two distinct periods, one in March and one in April, characterized by different dust transport paths. The dust aerosol layers were studied over 18 EARLINET stations, examining aerosol characteristics during March and April in four different regions (M-I, M-II, M-III, and M-IV and A-I, A-II, A-III, and A-IV, respectively), focusing on parameters such as aerosol layer thickness, center of mass (CoM), lidar ratio (LR), particle linear depolarization ratio (PLDR), and Ångström exponents (ÅE). In March, regions exhibited varying dust geometrical and optical properties, with mean CoM values ranging from approximately 3.5 to 4.8 km, and mean LR values typically between 36 and 54 sr. PLDR values indicated the presence of both pure and mixed dust aerosols, with values ranging from 0.20 to 0.32 at 355 nm and 0.24 to 0.31 at 532 nm. ÅE values suggested a range of particle sizes, with some regions showing a predominance of coarse particles. Aerosol Optical Depth (AOD) simulations from the NAAPS model indicated significant dust activity across Europe, with AOD values reaching up to 1.60. In April, dust aerosol layers were observed between 3.2 to 5.2 km. Mean LR values typically ranged from 35 to 51 sr at both 355 nm and 532 nm, while PLDR values confirmed the presence of dust aerosols, with mean values between 0.22 and 0.31 at 355 nm and 0.25 to 0.31 at 532 nm. The ÅE values suggested a mixture of particle sizes. The AOD values in April were generally lower, not exceeding 0.8, indicating a less intense dust presence compared to March. The findings highlight spatial and temporal variations in aerosol characteristics across the regions, during the distinctive periods. From 15 to 16 March 2022, Saharan dust significantly reduced UV-B radiation by approximately 14% over the ATZ station (Athens, GR). Backward air mass trajectories showed that the dust originated from the Western and Central Sahara when, during this specific case, the air mass trajectories passed over GRA (Granada, ES) and PAY (Payerne, CH) before reaching ATZ, maintaining high relative humidity and almost stable aerosol properties throughout its transport. Lidar data revealed elevated aerosol backscatter (baer) and PLDR values, combined with low LR and ÅE values, indicative of pure dust aerosols. [ABSTRACT FROM AUTHOR]

Published

2024

5. Analyzing Trends in Saharan Dust Concentration and Its Relation to Sargassum Blooms in the Eastern Caribbean

Author

José J. Hernández Ayala and Rafael Méndez-Tejeda

Subjects

Saharan dust, Sargassum, sea surface temperatures, chlorophyll, Caribbean, Oceanography, GC1-1581

Abstract

This study investigates the temporal trends and correlations between Saharan dust mass concentration densities (DMCD) and Sargassum concentrations (SCT) in the tropical North Atlantic. Average DMCD data for June, July, and August from 1980 to 2022, alongside SCT data for the same months from 2012 to 2022, were analyzed using Mann–Kendall tests for trends and lagged regression models to assess whether higher Saharan dust levels correlate with Sargassum outbreaks in the region. A comprehensive analysis reveals a significant upward trend in Saharan dust quantities over the study period, with the summer months of June, July, and August exhibiting consistent increases. Notably, 2018 and 2020 recorded the highest mean DMCD levels, with June showing the most significant increasing trend, peaking in 2019. These findings are consistent with previous studies indicating a continuous elevation in Saharan dust concentrations in the tropical atmosphere of the North Atlantic. Simultaneously, Sargassum concentrations also show a notable increasing trend, particularly in 2018, which experienced both peak SCT and elevated DMCD levels. Mann–Kendall tests confirm statistically significant upward trends in both Saharan dust and Sargassum concentrations. Simple linear regression and lagged regression analyses reveal positive correlations between DMCD and SCT, highlighting a temporal component with stronger associations observed in July and the overall June–July–August (JJA) period. These results underscore the potential contribution of elevated Saharan dust concentrations to the recent surge in Sargassum outbreaks in the tropical North Atlantic. Furthermore, the results from forward stepwise regression (FSR) models indicate that DMCD and chlorophyll (CHLO) are the most critical predictors of SCT for the summer months, while sea surface temperature (SST) was not a significant predictor. These findings emphasize the importance of monitoring Saharan dust and chlorophyll trends in the Eastern Caribbean, as both factors are essential for improving Sargassum modeling and prediction in the region. This study provides valuable insights into the climatic factors influencing marine ecosystems and highlights the need for integrated environmental monitoring to manage the impacts on coastal economies.

Published

2024

6. Aerosols Optical Properties Profile Characterization Over São Vicente, Cabo Verde, During the ASKOS Campaign

Author

Idrissa, Samira Moussa, do Rosário, Nilton Évora, Siomos, Nikolaos, Pisello, Anna Laura, Editorial Board Member, Hawkes, Dean, Editorial Board Member, Bougdah, Hocine, Editorial Board Member, Rosso, Federica, Editorial Board Member, Abdalla, Hassan, Editorial Board Member, Boemi, Sofia-Natalia, Editorial Board Member, Mohareb, Nabil, Editorial Board Member, Mesbah Elkaffas, Saleh, Editorial Board Member, Bozonnet, Emmanuel, Editorial Board Member, Pignatta, Gloria, Editorial Board Member, Mahgoub, Yasser, Editorial Board Member, De Bonis, Luciano, Editorial Board Member, Kostopoulou, Stella, Editorial Board Member, Pradhan, Biswajeet, Editorial Board Member, Abdul Mannan, Md., Editorial Board Member, Alalouch, Chaham, Editorial Board Member, Gawad, Iman O., Editorial Board Member, Nayyar, Anand, Editorial Board Member, Amer, Mourad, Series Editor, Fomba, Khanneh Wadinga, editor, Tchanche Fankam, Bertrand, editor, Mellouki, Abdelwahid, editor, Westervelt, Daniel M., editor, and Giordano, Michael R., editor

Published

2024

7. Identifying External Sources of High PM2.5 Concentrations at Urban Air Monitors: An Application to North-Central Texas, U.S.

Author

Hudak, Paul F.

Subjects

PARTICULATE matter, AIR quality, ATMOSPHERIC transport, DUST, STANDARD deviations

Abstract

This objective of this study was to identify external sources of high particulate concentrations at a monitoring station in northcentral Texas, U.S. Concentrations of particulate matter finer than 2.5 microns (PM2.5), averaged over 24 hours, were plotted over a five-year period, from 2018 through 2022. PM2.5 concentrations ranged from 0.2 μg/m³ to 52.0 μg/m³, with a mean of 7.4 μg/m³ and standard deviation of 4.1 μg/m³. For 23 PM2.5 samples (of 1,667 total samples) with concentrations above 20 μg/m³, backward atmospheric transport trajectories and satellite data were used to identify likely external sources. Saharan dust affected all but two of the 23 samples with the highest PM2.5 concentrations. Smoke from wildfires in the Pacific Northwest and Great Plains (Oklahoma and Kansas) affected the other two of 23 elevated samples. Results illustrate a substantial influence of Saharan dust on PM2.5 concentrations, especially in summer months, near the western edge of its westward transport trajectory. Monitoring and forecasting Saharan dust incursions should help inform regional air quality advisories. [ABSTRACT FROM AUTHOR]

Published

2024

8. Distinguishing Saharan Dust Plume Sources in the Tropical Atlantic Using Elemental Indicators.

Author

Yeager, Daniel E. and Morris, Vernon R.

Subjects

*DUST, *INDUCTIVELY coupled plasma mass spectrometry, *ATMOSPHERIC aerosols

Abstract

The Sahara Desert is the largest contributor of global atmospheric dust aerosols impacting regional climate, health, and ecosystems. The climate effects of these dust aerosols remain uncertain due, in part, to climate model uncertainty of Saharan source region contributions and aerosol microphysical properties. This study distinguishes source region elemental signatures of Saharan dust aerosols sampled during the 2015 Aerosols Ocean Sciences Expedition (AEROSE) in the tropical Atlantic. During the 4-week campaign, cascade impactors size-dependently collected airborne Saharan dust particulate upon glass microfiber filters. Inductively Coupled Plasma Mass Spectrometry (ICP-MS) analysis differentiated metal isotope concentrations within filter samples from various AEROSE dust sampling periods. Back-trajectory analysis and NOAA satellite aerosol optical depth retrievals confirmed source regions of AEROSE '15 dust samples. Pearson correlational statistics of source region activity and dust isotope concentrations distinguished the elemental signatures of North African potential source areas (PSAs). This study confirmed that elemental indicators of these PSAs remain detectable within dust samples collected far into the marine boundary layer of the tropical Atlantic. Changes detected in dust elemental indicators occurred on sub-weekly timescales across relatively small sampling distances along the 23W parallel of the tropical Atlantic. PSA-2 emissions, covering the western coast of the Sahara, were very strongly correlated (R2 > 0.79) with Ca-44 isotope ratios in AEROSE dust samples; PSA-2.5 emissions, covering eastern Mauritania and western Mali, were very strongly correlated with K-39 ratios; PSA-3 emissions, spanning southwestern Algeria and eastern Mali, were very strongly correlated with Fe-57 and Ti-48 ratios. The abundance of Ca isotopes from PSA-2 was attributed to calcite minerals from dry lakebeds and phosphorous mining activities in Western Sahara, based on source region analysis. The correlation between K isotope ratios and PSA-2.5 was a likely indicator of illite minerals near the El Djouf Desert region, according to corroboration with mineral mapping studies. Fe and Ti ratio correlations with PSA-3 observed in this study were likely indicators of iron and titanium oxides from Sahelian sources still detectable in Atlantic Ocean observations. The rapid changes in isotope chemistry found in AEROSE dust samples provide a unique marker of Saharan source regions and their relative contributions to desert outflows in the Atlantic. These elemental indicators provide source region apportionments of Sahara Desert aerosol flux and deposition into the Atlantic Ocean, as well as a basis for model and satellite validation of Saharan dust emissions for regional climate assessments. [ABSTRACT FROM AUTHOR]

Published

2024

9. Environmental control of interannual and seasonal variability in dinoflagellate cyst export flux over 18 years in the Cape Blanc upwelling region (Mauritania).

Author

Roza, Surya Eldo V., Versteegh, Gerard J. M., Pospelova, Vera, and Zonneveld, Karin A. F.

Subjects

DINOFLAGELLATE cysts, OCEAN temperature, EFFECT of human beings on climate change, ECOSYSTEMS, FOSSIL microorganisms, WIND speed, SPRING

Abstract

The increasing threat of anthropogenic environment and climate change amplifies the urgency to investigate the effect of these changes on marine ecosystems. We provide information about the export flux of organic-walled dinoflagellate cysts between 2003 and 2020 in the upwelling ecosystem off Cape Blanc (Mauritania), one of the world's most productive regions. We compared the cyst export flux with variability in environmental parameters, such as wind speed, wind direction, dust emission, sea surface temperature (SST), SST difference between trap location and open ocean (SSTa), and chlorophyll-a concentration. This information is valuable to determine the ecological signal of dinoflagellate cysts that could be applied in recent and paleo records. The total export production of dinoflagellate cysts fluctuated between 0 - 1.18 x 105 cystsm-2 d-1 for the heterotrophs and 0 - 1.06 x 104 cystsm-2 d-1 for the photo-/mixotrophs. The export productions of both groups were in line with changes in upwelling intensity, which in most years, intensified in spring - summer. Dinoflagellate cyst association was dominated by heterotrophic taxa that formed an average of 94% of the association throughout the sediment trap record. A strong interannual variation in the cyst export fluxes, as well as the association composition was observed in the record. We identified five groups that showed comparable variability in export production with changes in environmental conditions: (1) maximal upwelling; Echinidinium delicatum/granulatum, E. transparantum/zonneveldiae, Echinidinium spp., Trinovantedinium spp., and Protoperidinium latidorsale, (2) combined maximal upwelling and dust input; Archaeperidinium spp., P. americanum, P. stellatum, and P. subinerme, (3) upwelling relaxation; Gymnodinium spp. and L. polyedra, (4) warm surface waters; Bitectatodinium spongium and Protoceratium reticulatum, (5) species with no specific relationship to the studied environmental variables; Brigantedinium spp., E. aculeatum, Impagidinium aculeatum, P. conicum, P. monospinum, Pentapharsodinium dalei, and Spiniferites spp. The sediment trap record documented a gradual shift in the cyst taxa association that co-occurred with the gradual increase of Saharan dust input to the region, notably after 2008. The cyst association contained five photo-/mixotrophic taxa that were formed by potentially toxic dinoflagellates. The latter could cause threats to the socio-economy of coastal communities. [ABSTRACT FROM AUTHOR]

Published

2024

10. Influence of Saharan Dust on the Composition of Urban Aerosols in Palermo City (Italy).

Author

Varrica, Daniela and Alaimo, Maria Grazia

Subjects

*DUST, *RARE earth metals, *ATMOSPHERIC sciences, *AEROSOLS, *TRACE elements, *AIR masses, *CLAY minerals

Abstract

The Mediterranean Basin is involved in a recurring phenomenon wherein air masses laden with dust from North Africa impact the southern regions of the European continent. Saharan dust has been associated with increased mortality and respiratory symptoms. Palermo is a large coastal city, and in addition to the impact of desert dust particles, it has a mixture of anthropogenic sources of pollutants. In this study, we collected Saharan dust samples during August 2022 and October 2023, following a high-intensity Saharan dust event, and measured concentrations of 33 major and trace elements as well as Rare Earth Elements (REE). The mineralogical characterization of the deposition dust collected during Saharan events revealed calcite, dolomite, quartz, and clay minerals. The presence of palygorskite is indicative of Saharan events. Seven elements (Ca, Mg, Al, Ti, Fe, K, and Na) account for 98% of the total analyzed inorganic burden. Elemental ratios are valuable tools in atmospheric sciences for estimating sources of air masses. The results highlight that the city of Palermo is mainly affected by dust from the north-western Sahara. [ABSTRACT FROM AUTHOR]

Published

2024

11. Microorganisms Isolated from Saharan Dust Intrusions in the Canary Islands and Processes of Mineral Atmospherogenesis.

Author

Navarro, Azahara, del Moral, Ana, de Pablos, Irene, Delgado, Rafael, Párraga, Jesús, Martín-García, Juan M., and Martínez-Checa, Fernando

Subjects

DUST, GLOBAL warming, EXTREME environments, PLANT growth-promoting rhizobacteria, X-ray photoelectron spectroscopy, AIR pollution, ENDOTOXINS

Abstract

Global warming due to climate change has increased the frequency of sand and dust storms that affect air quality and ecosystems in general, contributing to air pollution. The Sahara Desert is the most potent emitter of atmospheric dust. The atmosphere is an extreme environment and microorganisms living in the troposphere are exposed to greater ultraviolet radiation, desiccation, low temperatures and nutrient deprivation than in other habitats. The Iberian Peninsula, and specifically the Canary Islands—due to its strategic location—is one of the regions that receive more Saharan dust particles annually, increasing year after year, although culturable microorganisms had previously never been described. In the present work, dust samples were collected from three calima events in the Canary Islands between 2021 and 2022. The sizes, mineralogical compositions and chemical compositions of dust particles were determined by laser diffraction, X-ray diffraction (XRD) and X-ray photoelectron spectroscopy (XPS), respectively. Particle morphology and biological features were also studied by scanning electron microscopy (SEM-EDX) and confocal laser scanning microscopy (CLSM). The mineral–bacteria interactions were described from microscopic observations, which revealed the presence of iberulites and small neoformed kaolinite crystals in association with bacteria. This article defines the term "mineral atmospherogenesis" and its variant, "mineral bioatmospherogenesis", through microbial interaction. This is the first described case of kaolinite produced through mineral bioatmospherogenesis. The bacterial growth in atmospheric dust was illustrated in SEM images, constituting a novel finding. Twenty-three culturable microorganisms were isolated and identified by 16S rRNA sequencing. Members of the phyla Pseudomonadota, Bacillota and Actinomycetota have been found. Some of these microorganisms, such as Peribacillus frigoritolerans, have Plant Growth-Promoting Rhizobacteria (PGPR) properties. Potential human pathogenic bacteria such as Acinetobacter lwoffii were also found. The presence of desert dust and iberulites in the Canary Islands, together with transported biological components such as bacteria, could have a significant impact on the ecosystem and human health. [ABSTRACT FROM AUTHOR]

Published

2024

12. Approach into the influence of Saharan dust on the physicochemical properties of PM2.5 in Monterrey, México.

Author

Martinez-Verduzco, R. O., Reyna-Gomez, L. M., Cruz-López, A., Carrillo-Avila, J. R., Valdez-Cavazos, A., and Suárez-Vázquez, S. I.

Subjects

EMISSIONS (Air pollution), DUST, PARTICLE size distribution, CALCIUM sulfate, ALUMINUM sulfate, METHYL methacrylate

Abstract

In this work, the influence of Saharan dust (S.D.) on the physicochemical properties of the PM2.5 in the Monterrey Metropolitan Area in Mexico is studied. PM2.5 sampling was carried out in a strategic sampling point during the alert peak of Saharan dust in July 2021. Additional samples were taken during the same weather season for comparison purposes. The characterization of the elemental composition in PM2.5 was carried out by FRX and EDS. The crystalline phases and the morphology were investigated by XRD and SEM, respectively. Organic matter was analyzed by TGA. Results revealed that S.D. contributes to the increase of > 22% of PM2.5 of the MMA. This increase in PM2.5concentration comes together with the increase of the elemental concentration of S and Al in 13 and 35 wt% (FRX) respectively, as calcium sulfates and aluminum oxides. A decrease in the Fe content of S.D. is attributed to the warm season and/or the long distance from the original source. In addition, the arrival of the Saharan dust decreases approximately 10% the amount of organic matter in PM2.5 samples as well as the particle size distribution from 0.660 to 0.469 μm with significant changes in the particle morphology and in the crystalline compounds. During the free days of Saharan dust in the MMA, the chemical composition of PM2.5 is associated with crustal suspended particles as well as burning fuels and industrial activities emissions located near the sampling point. Zn could require more attention due to its possible inhalation risk. [ABSTRACT FROM AUTHOR]

Published

2024

13. Increasing frequency and changing nature of Saharan dust storm events in the Carpathian Basin (2019–2023) – the new normal?

Author

György Varga, Ágnes Rostási, Aida Meiramova, Pavla Dagsson-Waldhauserová, and Fruzsina Gresina

Subjects

saharan dust, climate change, carpathian basin, grain size, Geography (General), G1-922

Abstract

The number and intensity of Saharan dust storm events identified in Europe has been increasing over the last decade. This can be explained by the role of ongoing climate change. An extension of previous studies covering a 40-year period is presented in this paper, with new data on the frequency, synoptic meteorological background, source areas, grain size, grain shape and general mineralogy of deposited dust for the period 2019–2023 in the Carpathian Basin. A total of 55 dust storm episodes have been identified in the region over the five-year period, which is significantly higher than the long-term average. The classification based on synoptic meteorological background clearly showed that the frequency of circulation types with a more pronounced meridional component increased and dust material reached further north more frequently than before. In several cases, large amounts of dust were deposited, from which samples were collected and subjected to detailed granulometric analysis. The varied grain size data showed that coarse silt (20–62.5 μm) and sand (62.5 < μm) fractions were also present in large quantities in the transported dust material.

Published

2023

14. Use of Low-Cost Sensors to Study Atmospheric Particulate Matter Concentrations: Limitations and Benefits Discussed through the Analysis of Three Case Studies in Palermo, Sicily

Author

Filippo Brugnone, Luciana Randazzo, and Sergio Calabrese

Subjects

particulate matter, air pollution, low-cost sensors, Saharan dust, wood smoke, fireworks, Chemical technology, TP1-1185

Abstract

The paper discusses the results of the concentrations of atmospheric particulate matter, in the PM2.5 and PM10 fractions, acquired by two low-cost sensors. The research was carried out from 1 July 2023 to 30 June 2024, in Palermo, Sicily. The results obtained from two systems equipped with the same sensor model were compared. Excellent linear correlation was observed between the results, with differences in measurements falling within instrumental accuracy. Two instruments equipped with different sensors, models Novasense SDS011 and Plantower PMSA003, were placed at the same site. These were complemented by a weather station to measure meteorological parameters. Upon comparing the atmospheric particulate matter concentrations measured by the two instruments, it was observed that there was a good linear correlation for PM2.5 and a poor linear correlation for PM10. Additionally, the PMSA003 sensor appeared to consistently record higher concentrations than the SDS011 sensor. During periods influenced by natural sources and/or anthropogenic activities at the regional and/or local scale, i.e., the dispersal of Saharan sands, forest fires, and local events using fireworks, abnormal concentrations of atmospheric particulate matter were detected. Despite the inherent limitations in precision and accuracy, both low-cost instruments were able to identify periods with abnormal concentrations of atmospheric particulate matter, regardless of their source or type.

Published

2024

15. Air Quality Assessment in Six Major Greek Cities with an Emphasis on the Athens Metropolitan Region

Author

Konstantinos Dimitriou and Nikolaos Mihalopoulos

Subjects

PM2.5, Saharan dust, air quality index, biomass burning, benzene, Meteorology. Climatology, QC851-999

Abstract

To assess the impact of air pollution on human health in multiple urban areas in Greece, hourly concentrations of common air pollutants (CO, NO2, O3, SO2, PM10, and PM2.5) from 11 monitoring stations in six major Greek cities (Athens, Thessaloniki, Patra, Volos, Ioannina, and Kozani), were used to implement the U.S. EPA’s Air Quality Index (AQI) during a seven-year period (2016–2022). In Athens, the capital city of Greece, hourly PM10 and PM2.5 concentrations were also studied in relation to the prevailing wind patterns, while major PM10 episodes exceeding the official daily EU limit (50 μg/m3) were analyzed using the Potential Source Contribution Function (PSCF) in terms of the air mass origin. According to the AQI results, PM10 and PM2.5 were by far the most hazardous pollutants associated with moderate and unhealthy conditions in all the studied areas. In addition, in Athens, Thessaloniki, and Patra, where the benzene levels were also studied, a potential inhalation cancer risk (>1.0 × 10−6) was detected. In Athens, Saharan dust intrusions were associated with downgraded air quality, whilst regional transport and the accumulation of local emissions triggered increased PM10 and PM2.5 levels in traffic sites, especially during cold periods. Our study highlights the need for the development of early warning systems and emission abatement strategies for PM pollution in Greece.

Published

2024

16. Large-Scale Network-Based Observations of a Saharan Dust Event across the European Continent in Spring 2022

Author

Christina-Anna Papanikolaou, Alexandros Papayannis, Marilena Gidarakou, Sabur F. Abdullaev, Nicolae Ajtai, Holger Baars, Dimitris Balis, Daniele Bortoli, Juan Antonio Bravo-Aranda, Martine Collaud-Coen, Benedetto de Rosa, Davide Dionisi, Kostas Eleftheratos, Ronny Engelmann, Athena A. Floutsi, Jesús Abril-Gago, Philippe Goloub, Giovanni Giuliano, Pilar Gumà-Claramunt, Julian Hofer, Qiaoyun Hu, Mika Komppula, Eleni Marinou, Giovanni Martucci, Ina Mattis, Konstantinos Michailidis, Constantino Muñoz-Porcar, Maria Mylonaki, Michail Mytilinaios, Doina Nicolae, Alejandro Rodríguez-Gómez, Vanda Salgueiro, Xiaoxia Shang, Iwona S. Stachlewska, Horațiu Ioan Ștefănie, Dominika M. Szczepanik, Thomas Trickl, Hannes Vogelmann, and Kalliopi Artemis Voudouri

Subjects

EARLINET, lidar, aerosols, Saharan dust, optical properties, CALIPSO, Science

Abstract

Between 14 March and 21 April 2022, an extensive investigation of an extraordinary Saharan dust intrusion over Europe was performed based on lidar measurements obtained by the European Aerosol Research Lidar Network (EARLINET). The dust episode was divided into two distinct periods, one in March and one in April, characterized by different dust transport paths. The dust aerosol layers were studied over 18 EARLINET stations, examining aerosol characteristics during March and April in four different regions (M-I, M-II, M-III, and M-IV and A-I, A-II, A-III, and A-IV, respectively), focusing on parameters such as aerosol layer thickness, center of mass (CoM), lidar ratio (LR), particle linear depolarization ratio (PLDR), and Ångström exponents (ÅE). In March, regions exhibited varying dust geometrical and optical properties, with mean CoM values ranging from approximately 3.5 to 4.8 km, and mean LR values typically between 36 and 54 sr. PLDR values indicated the presence of both pure and mixed dust aerosols, with values ranging from 0.20 to 0.32 at 355 nm and 0.24 to 0.31 at 532 nm. ÅE values suggested a range of particle sizes, with some regions showing a predominance of coarse particles. Aerosol Optical Depth (AOD) simulations from the NAAPS model indicated significant dust activity across Europe, with AOD values reaching up to 1.60. In April, dust aerosol layers were observed between 3.2 to 5.2 km. Mean LR values typically ranged from 35 to 51 sr at both 355 nm and 532 nm, while PLDR values confirmed the presence of dust aerosols, with mean values between 0.22 and 0.31 at 355 nm and 0.25 to 0.31 at 532 nm. The ÅE values suggested a mixture of particle sizes. The AOD values in April were generally lower, not exceeding 0.8, indicating a less intense dust presence compared to March. The findings highlight spatial and temporal variations in aerosol characteristics across the regions, during the distinctive periods. From 15 to 16 March 2022, Saharan dust significantly reduced UV-B radiation by approximately 14% over the ATZ station (Athens, GR). Backward air mass trajectories showed that the dust originated from the Western and Central Sahara when, during this specific case, the air mass trajectories passed over GRA (Granada, ES) and PAY (Payerne, CH) before reaching ATZ, maintaining high relative humidity and almost stable aerosol properties throughout its transport. Lidar data revealed elevated aerosol backscatter (baer) and PLDR values, combined with low LR and ÅE values, indicative of pure dust aerosols.

Published

2024

17. Radiative and Microphysical Impacts of the Saharan Dust on Two Concurrent Tropical Cyclones: Danielle and Earl (2010).

Author

Pan, Bowen, Wang, Yuan, Lin, Yun, Hsieh, Jen‐Shan, Lavallee, Michael, Zhao, Lijun, and Zhang, Renyi

Subjects

TROPICAL cyclones, HURRICANE forecasting, METEOROLOGICAL research, OCEAN temperature, WEATHER forecasting, RADIATIVE transfer, DUST, MINERAL dusts

Abstract

Saharan dust exerts profound impacts on the genesis and intensification of tropical cyclones (TCs). Such impacts on various stages of the TCs have yet to be explored. In this study, we utilize the Cloud‐Resolving weather research and forecasting model (WRF) to investigate the relative importance of the microphysical and radiative effects of dust on two hurricanes (Earl and Danielle) at different life stages under similar dynamical conditions in 2010. Both TCs were embedded in a dusty environment throughout their lifetime. A new dust ice nucleation scheme was implemented into the aerosol‐aware Texas A&M University two‐moment microphysical scheme in WRF. Moreover, the dust radiative effect was included in the Goddard Shortwave Scheme of WRF. Our sensitivity experiments show that the radiative effect of dust (DRAD) amplified the mid‐level ridge in the Central Atlantic Ocean through temperature perturbation, changing the tracks of Danielle and Earl. Further analyses reveal an early shift of Danielle's maximum intensity for 12 hours but a significantly suppressed Earl in DRAD. In addition, the microphysical effect of dust had little impact on the large‐scale dynamical fields and storm tracks. The inclusion of dust as ice nucleation particles results in more variations in the intensity of Danielle and Earl than in other scenarios. This is owing to the higher maximum diabatic heating rate in the rainband region that perturbs the size of the TC. This study shows the dominant dust radiative effects on both intensity and track of the storm. In addition, there is evidence that dust suppresses the early stage TC but provides favorable conditions for matured TC. Both findings have profound implications for hurricane forecast and address the importance of accounting for detailed cloud microphysics and aerosol‐TC interactions in the operational forecasting models. Plain Language Summary: This modeling study assesses how dust from the Saharan Desert affects tropical cyclones (TCs). Dust modifies the radiative transfer by reflecting and absorbing sunlight (the radiative effect) and hence the environmental temperature profile. In addition, dust also changes cloud processes (the dust microphysical effect) that perturbs the cloud distribution. A cloud‐resolving model was used to assess the dust impacts on two TCs at different development stages, that is, Danielle and Earl (2010). We found that the radiative effect of dust plays an important role in the intensity and path of both TCs. Specifically, the radiative effects of dust weakened the early stage TC Earl, resulted in an early shift of maximum intensity of the matured TC Danielle, and perturbed the path of both TCs. The dust microphysics effect, on the other hand, had little impact on the TC environment and its path but induced larger variations in the intensity of both TCs. This study reveals that dust exhibits distinct effects depending on the stage of the TC development, showing that dust suppresses the early stage TC but provides favorable conditions for the matured TC. Key Points: A dust‐related ice nucleating scheme and radiation parameterizations were implemented in the aerosol‐aware weather research and forecasting modelThe radiative effect of dust plays a larger role in the large‐scale environment and intensity of tropical cyclones (TCs) than the microphysical effectThe dust effect suppresses the early stage TC but provides favorable conditions for matured TC [ABSTRACT FROM AUTHOR]

Published

2024

18. Godzilla mineral dust and La Soufrière volcanic ash fallout immediately stimulate marine microbial phosphate uptake.

Author

Elliott, Hope Elizabeth, Popendorf, Kimberly J., Blades, Edmund, Royer, Haley M., Pollier, Clément G. L., Oehlert, Amanda M., Kukkadapu, Ravi, Ault, Andrew, and Gaston, Cassandra J.

Subjects

VOLCANIC ash, tuff, etc., MINERAL dusts, DUST, ATMOSPHERIC deposition, BIOMASS energy, DUST storms, ALKALINE phosphatase

Abstract

During the “Godzilla” dust storm of June 2020, unusually high fluxes of mineral dust traveled across the Atlantic from the Sahara Desert, reaching the Caribbean Basin, Gulf Coast, and southeastern United States. Additionally, an eruption of the La Soufrière volcano on St. Vincent in April 2021 generated substantial ashfall in the southeastern Caribbean. While many studies have analyzed mineral dust’s ability to relieve nutrient limitation of phosphorus (P) in the P-stressed North Atlantic, less is known about the impact of extreme events and other natural aerosols on fluxes of P into seawater and from seawater into marine microbial cells. We quantified P and iron (Fe) content in mineral dust from the Godzilla dust storm and volcanic ash from the La Soufrière eruption collected at Ragged Point, Barbados. We also performed seawater incubations to assess the marine microbial response to aerosol deposition. Using environmentally-relevant concentrations of atmospheric particles for within the ocean’s mixed layer allowed us to draw realistic conclusions about how these deposition events impacted P cycling in situ. Volcanic ash has lower P content than mineral dust, and P in volcanic ash is far less soluble (~1%) than assumed in current atmospheric deposition models. Adding mineral dust and the volcanic ash leachate in concentrations representing different deposition scenarios increased soluble reactive phosphorus (SRP) concentrations in coastal seawater by ~7-32 nM. Phosphate uptake rate was stimulated in coastal seawater after either mineral dust or volcanic ash deposition at aerosol concentrations relevant to the Godzilla dust event, with ash eliciting the fastest uptake rate. Furthermore, high concentrations of both the mineral dust and volcanic ash led to slightly elevated alkaline phosphatase activity (APA) compared to the relevant controls, indicating higher potential for use of dissolved organic phosphorus (DOP) as a P source. Quantifying these aerosols’ impacts on P cycling is a significant step towards achieving a better understanding of their potential roles in relieving nutrient limitation and fueling the biological carbon pump. [ABSTRACT FROM AUTHOR]

Published

2024

19. Elemental ratios as tracers of the sources of mineral dust in north-eastern Sahara.

Author

Boraiy, M., El-Metwally, M., Borbon, A., Chevaillier, S., Laurent, B., Lafon, S., El Sanabary, F. F., Masmoudi, M., and Alfaro, S. C.

Subjects

DUST, MINERAL dusts, SILICA dust, X-ray fluorescence, ERGS (Landforms), SAND dunes, PLAYAS

Abstract

The objective of this study is to confirm the possibility of tracing sources of airborne mineral dust using elemental ratios. The region of study is the north-eastern part of the Sahara where dust compositional data were lacking; 272 mineral dust samples collected at 3 experimental stations of Egypt were analyzed by X-ray fluorescence. Based on the mineral dust concentration, 65% of the samples correspond to moderate (3–10 μg m−3), 22% to medium (10–25 μg m−3), and 13% to intense (> 25 μg m−3) dust events. The Ca/Al and (Mg + Ca)/Fe ratios were found to be strongly correlated and their ranges of variation to cover are more than one order of magnitude, which confirms their interest for the tracing of the dust sources. Using a combination of MODIS satellite observations, HYSPLIT back-trajectory analysis, and simulations with dust emission models, the large (> 6) and intermediate (2–6) Ca/Al ratios were shown to correspond to dust originating from saline playas (chotts) and calcareous surfaces, respectively. Conversely, the lowest (< 2) ratios correspond to dust emitted by siliceous sand seas (ergs). Therefore, a classification of the dust in 3 categories (erg-like, calcareous, and chott-like) based on Ca/Al is proposed. The events of moderate to medium intensity are dominated by chott-like and calcareous dust, which suggests that these sources are activated during erosion events of limited (local) extension. Conversely, the fact that the dust composition is more likely to be of the erg-like type during intense events underlines the dominant role played by sand dune fields during major erosion events. [ABSTRACT FROM AUTHOR]

Published

2024

20. Influence of Internal Climate System Forcing on the Relationship Between North Atlantic Tropical Cyclones and Saharan Dust.

Author

Zhang, Zhenxi and Zhou, Wen

Subjects

TROPICAL cyclones, ATLANTIC multidecadal oscillation, NORTH Atlantic oscillation, EL Nino, DUST, MODES of variability (Climatology)

Abstract

This study explores the role of internal climate system forcing in the relationship between dust and tropical cyclones (TCs). Here internal climate system forcing includes the Atlantic Multidecadal Oscillation (AMO), Atlantic Meridional Mode (AMM), Sahel rainfall, North Atlantic Oscillation (NAO), and El Niño–Southern Oscillation (ENSO). The dust‐TC relationship is evaluated through statistical analyses of 42‐year (1980–2021) reanalysis and observation data sets for TCs and the Saharan dust plume over the North Atlantic. In August, the negative correlation between dust and TCs in the region east of the Florida Peninsula and north of the Caribbean Sea is inhibited by AMO, AMM, and ENSO and promoted by NAO. In September, the positive correlation between dust and TCs in the eastern US and its adjacent ocean is inhibited by Sahel rainfall and promoted by AMO, AMM, and ENSO. In October, the positive correlation between dust and TCs in the southeastern US is promoted by Sahel rainfall and inhibited by AMO, AMM, and ENSO. The leading climate mode influence on the dust‐TC relationship comes from AMO in August and September, and ENSO in October. The dust‐TC relationship in September and October indicates an increase in TC landfalls over the continental US accompanied by a strengthened Saharan dust plume, which further affects the hydrology of the continental US on an interdecadal timescale by reducing land moisture in September and increasing it in October, as determined by the location of TC landfalls, topography, and the impact of climate mode. Plain Language Summary: The relationship between North Atlantic tropical cyclones (TCs) and the Saharan dust plume is an important scientific question. It is found in this study that the response of TCs to variation in the Saharan dust plume, including changes in TC intensity, track, and genesis, varies monthly during the storm season. As far as the effects of climate change on North Atlantic TCs, Saharan dust is differentiated from internal forcing of the climate system. Therefore the role of internal climate system forcing in the dust‐TC relationship is explored in this study. The largest climate mode influence on the dust‐TC relationship comes from the sea surface temperature over the North Atlantic in August and September, and El Niño–Southern Oscillation in October. On the other hand, the dust‐TC relationship is found to be related to interdecadal variability in the hydrology of the continental US. In September and October, an increase in TC landfalls over the continental US accompanied by a strengthened Saharan dust plume can reduce land moisture in September and increase it in October, depending on the location of TC landfalls, topography, and the impact of climate mode. Key Points: The response of tropical cyclones (TCs) to the Saharan dust plume, including TC intensity, track, and genesis, varies monthly during the storm seasonThe leading climate mode influence on the dust‐TC relationship comes from Atlantic Multidecadal Oscillation in August and September, and El Niño–Southern Oscillation in OctoberThe dust‐TC relationship affects the hydrology of US on an interdecadal timescale, determined by TC landfalls, topography, and climate mode [ABSTRACT FROM AUTHOR]

Published

2024

21. Weathering Saharan dust beyond the Spanish Mediterranean Basin: An interdisciplinary dialogue.

Author

Sabin, Lucy and Cantos, Jorge Olcina

Subjects

*DUST, *WEATHERING, *POLITICAL ecology, *AIR quality, *MINERAL dusts, *POWER (Social sciences)

Abstract

This interdisciplinary dialogue draws on climatology and cultural studies to explore the phenomenon of "Saharan dust" that passes through and beyond the Spanish Mediterranean Basin. The dialogic process seeks to unearth the power relations within which weather stories and the authors are always already entangled, with a view to re-imagining weather writing and climatic storytelling in decolonial terms. Our parallel inquiries trace how origin stories, material mobilities, atmospheres, and environmental regulation work to codify the aeolian dust as an intrusion across borders. Drawing on critical theory, we argue that this weather "from" the Sahara Desert is othered in Eurocentric weather narratives, mapping onto geopolitical logic of "Fortress Europe". Our research is instructed by postcolonial thought, political ecology, and the speculative feminist position of weathering. Through critical engagement with science in context, we dwell lastly on African air quality and experiences of weathering atmospheric dust further upwind. Our concluding comments speculatively drift with Mediterranean winds to animate a positionality of middleness. [ABSTRACT FROM AUTHOR]

Published

2023

22. Ambient air quality assessment at the airports based on a meteorological perspective.

Author

Birinci, Enes, Denizoğlu, Muhammed, Özdemir, Hüseyin, Özdemir, Emrah Tuncay, and Deniz, Ali

Subjects

AIR quality, AIRPORTS, AIR quality monitoring stations, EMISSIONS (Air pollution), MINERAL dusts, PARTICULATE matter

Abstract

Natural mineral dust episodes elevate particle concentrations and eventually decrease air quality. Air pollutant emissions from aircraft, airport ground operations, and long-range dust transport are producing problems for the aviation sector. Dust transport from the Sahara Desert, one of the primary dust sources globally, significantly affects the eastern Mediterranean basin, including Türkiye. This study investigates the effect of long-range dust transport on particulate matter (PM) concentrations at Turkish airports. Three different approaches were used to analyse dust episodes in the study area. Firstly, routine reports of meteorological conditions at the airports were investigated. For this purpose, airport routine meteorological reports (Metar) and aviation-selected special weather report (Speci) codes, recorded at 11 airports from 2012 to 2021, were used to determine the dust episode days. Secondly, the hourly PM measurement dataset was analyzed from the closest air quality monitoring stations to the airports. Finally, regional atmospheric model results and backward-trajectory analysis were used to validate the dust episodes and determine the dust origin. Results showed that 163 dust episodes occurred during the study period, 17% from North Africa and 12% from the Mediterranean region. [ABSTRACT FROM AUTHOR]

Published

2023

23. Environmental control of interannual and seasonal variability in dinoflagellate cyst export flux over 18 years in the Cape Blanc upwelling region (Mauritania)

Author

Surya Eldo V. Roza, Gerard J. M. Versteegh, Vera Pospelova, and Karin A. F. Zonneveld

Subjects

dinoflagellate cysts, ecology, coastal upwelling, Saharan dust, interannual variability, ecosystem change, Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

The increasing threat of anthropogenic environment and climate change amplifies the urgency to investigate the effect of these changes on marine ecosystems. We provide information about the export flux of organic-walled dinoflagellate cysts between 2003 and 2020 in the upwelling ecosystem off Cape Blanc (Mauritania), one of the world’s most productive regions. We compared the cyst export flux with variability in environmental parameters, such as wind speed, wind direction, dust emission, sea surface temperature (SST), SST difference between trap location and open ocean (SSTa), and chlorophyll-a concentration. This information is valuable to determine the ecological signal of dinoflagellate cysts that could be applied in recent and paleo records. The total export production of dinoflagellate cysts fluctuated between 0 - 1.18 x 105 cysts m-2 d-1 for the heterotrophs and 0 - 1.06 x 104 cysts m-2 d-1 for the photo-/mixotrophs. The export productions of both groups were in line with changes in upwelling intensity, which in most years, intensified in spring - summer. Dinoflagellate cyst association was dominated by heterotrophic taxa that formed an average of 94% of the association throughout the sediment trap record. A strong interannual variation in the cyst export fluxes, as well as the association composition was observed in the record. We identified five groups that showed comparable variability in export production with changes in environmental conditions: (1) maximal upwelling; Echinidinium delicatum/granulatum, E. transparantum/zonneveldiae, Echinidinium spp., Trinovantedinium spp., and Protoperidinium latidorsale, (2) combined maximal upwelling and dust input; Archaeperidinium spp., P. americanum, P. stellatum, and P. subinerme, (3) upwelling relaxation; Gymnodinium spp. and L. polyedra, (4) warm surface waters; Bitectatodinium spongium and Protoceratium reticulatum, (5) species with no specific relationship to the studied environmental variables; Brigantedinium spp., E. aculeatum, Impagidinium aculeatum, P. conicum, P. monospinum, Pentapharsodinium dalei, and Spiniferites spp. The sediment trap record documented a gradual shift in the cyst taxa association that co-occurred with the gradual increase of Saharan dust input to the region, notably after 2008. The cyst association contained five photo-/mixotrophic taxa that were formed by potentially toxic dinoflagellates. The latter could cause threats to the socio-economy of coastal communities.

Published

2024

24. Saharan Dust and Childhood Respiratory Symptoms in Benin.

Author

McElroy, Sara, Dimitrova, Anna, Evan, Amato, and Benmarhnia, Tarik

Subjects

African dust, Saharan dust, children under-5, dust, low-to-middle-income countries, respiratory outcomes, Air Pollutants, Benin, Child, Dust, Humans, Particulate Matter, Poverty

Abstract

Mineral dust is one of the largest natural constituents of coarse particulate matter (PM10). Most of these dust emissions originate from northern Africa, and several hundred tera-grams of dust are emitted annually from this region. Previous evidence has linked dust PM10 to adverse respiratory outcomes in children. However, most of these studies have been from high-income countries (HICs) or examined dust from other regions of the world, mainly Asia. Evidence from low-to-middle-income countries (LMICs) in Africa is scarce. Respiratory infections are one of the leading causes of under-five mortality across the globe. However, there is a poignant disparity in studies examining these outcomes in children in the region where most dust is emitted. This study linked remotely sensed satellite data to a nationally representative survey to examine acute exposure to dust in children living in Benin using a time-stratified case-crossover analysis. We identified acute effects of exposure to dust and increased risk of cough in children under five. The effect of increased risk is strongest within two weeks of exposure and dissipates by four weeks. Children living in rural areas and households with lower income had a greater risk of adverse respiratory outcomes when exposed to dust. We could elucidate the specific period and conditions of increased risk for respiratory problems in children living in Benin.

Published

2022

25. Godzilla mineral dust and La Soufrière volcanic ash fallout immediately stimulate marine microbial phosphate uptake

Author

Hope Elizabeth Elliott, Kimberly J. Popendorf, Edmund Blades, Haley M. Royer, Clément G. L. Pollier, Amanda M. Oehlert, Ravi Kukkadapu, Andrew Ault, and Cassandra J. Gaston

Subjects

Saharan dust, volcano, deposition, phosphorus, biogeochemical, Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

During the “Godzilla” dust storm of June 2020, unusually high fluxes of mineral dust traveled across the Atlantic from the Sahara Desert, reaching the Caribbean Basin, Gulf Coast, and southeastern United States. Additionally, an eruption of the La Soufrière volcano on St. Vincent in April 2021 generated substantial ashfall in the southeastern Caribbean. While many studies have analyzed mineral dust’s ability to relieve nutrient limitation of phosphorus (P) in the P-stressed North Atlantic, less is known about the impact of extreme events and other natural aerosols on fluxes of P into seawater and from seawater into marine microbial cells. We quantified P and iron (Fe) content in mineral dust from the Godzilla dust storm and volcanic ash from the La Soufrière eruption collected at Ragged Point, Barbados. We also performed seawater incubations to assess the marine microbial response to aerosol deposition. Using environmentally-relevant concentrations of atmospheric particles for within the ocean’s mixed layer allowed us to draw realistic conclusions about how these deposition events impacted P cycling in situ. Volcanic ash has lower P content than mineral dust, and P in volcanic ash is far less soluble (~1%) than assumed in current atmospheric deposition models. Adding mineral dust and the volcanic ash leachate in concentrations representing different deposition scenarios increased soluble reactive phosphorus (SRP) concentrations in coastal seawater by ~7-32 nM. Phosphate uptake rate was stimulated in coastal seawater after either mineral dust or volcanic ash deposition at aerosol concentrations relevant to the Godzilla dust event, with ash eliciting the fastest uptake rate. Furthermore, high concentrations of both the mineral dust and volcanic ash led to slightly elevated alkaline phosphatase activity (APA) compared to the relevant controls, indicating higher potential for use of dissolved organic phosphorus (DOP) as a P source. Quantifying these aerosols’ impacts on P cycling is a significant step towards achieving a better understanding of their potential roles in relieving nutrient limitation and fueling the biological carbon pump.

Published

2024

26. Increasing frequency and changing nature of Saharan dust storm events in the Carpathian Basin (2019-2023) - the new normal?

Author

VARGA, GYÖRGY, ROSTÁSI, ÁGNES, MEIRAMOVA, AIDA, DAGSSON-WALDHAUSEROVÁ, PAVLA, and GRESINA, FRUZSINA

Subjects

*DUST storms, *GRAIN size, *DUST, *CLIMATE change

Abstract

The number and intensity of Saharan dust storm events identified in Europe has been increasing over the last decade. This can be explained by the role of ongoing climate change. An extension of previous studies covering a 40-year period is presented in this paper, with new data on the frequency, synoptic meteorological background, source areas, grain size, grain shape and general mineralogy of deposited dust for the period 2019-2023 in the Carpathian Basin. A total of 55 dust storm episodes have been identified in the region over the five-year period, which is significantly higher than the long-term average. The classification based on synoptic meteorological background clearly showed that the frequency of circulation types with a more pronounced meridional component increased and dust material reached further north more frequently than before. In several cases, large amounts of dust were deposited, from which samples were collected and subjected to detailed granulometric analysis. The varied grain size data showed that coarse silt (20-62.5 µm) and sand (62.5 < µm) fractions were also present in large quantities in the transported dust material. [ABSTRACT FROM AUTHOR]

Published

2023

27. Distinguishing Saharan Dust Plume Sources in the Tropical Atlantic Using Elemental Indicators

Author

Daniel E. Yeager and Vernon R. Morris

Subjects

mineral dust aerosols, Saharan dust, air quality, ICP-MS, HYSPLIT, AEROSE, Meteorology. Climatology, QC851-999

Abstract

The Sahara Desert is the largest contributor of global atmospheric dust aerosols impacting regional climate, health, and ecosystems. The climate effects of these dust aerosols remain uncertain due, in part, to climate model uncertainty of Saharan source region contributions and aerosol microphysical properties. This study distinguishes source region elemental signatures of Saharan dust aerosols sampled during the 2015 Aerosols Ocean Sciences Expedition (AEROSE) in the tropical Atlantic. During the 4-week campaign, cascade impactors size-dependently collected airborne Saharan dust particulate upon glass microfiber filters. Inductively Coupled Plasma Mass Spectrometry (ICP-MS) analysis differentiated metal isotope concentrations within filter samples from various AEROSE dust sampling periods. Back-trajectory analysis and NOAA satellite aerosol optical depth retrievals confirmed source regions of AEROSE ’15 dust samples. Pearson correlational statistics of source region activity and dust isotope concentrations distinguished the elemental signatures of North African potential source areas (PSAs). This study confirmed that elemental indicators of these PSAs remain detectable within dust samples collected far into the marine boundary layer of the tropical Atlantic. Changes detected in dust elemental indicators occurred on sub-weekly timescales across relatively small sampling distances along the 23W parallel of the tropical Atlantic. PSA-2 emissions, covering the western coast of the Sahara, were very strongly correlated (R2 > 0.79) with Ca-44 isotope ratios in AEROSE dust samples; PSA-2.5 emissions, covering eastern Mauritania and western Mali, were very strongly correlated with K-39 ratios; PSA-3 emissions, spanning southwestern Algeria and eastern Mali, were very strongly correlated with Fe-57 and Ti-48 ratios. The abundance of Ca isotopes from PSA-2 was attributed to calcite minerals from dry lakebeds and phosphorous mining activities in Western Sahara, based on source region analysis. The correlation between K isotope ratios and PSA-2.5 was a likely indicator of illite minerals near the El Djouf Desert region, according to corroboration with mineral mapping studies. Fe and Ti ratio correlations with PSA-3 observed in this study were likely indicators of iron and titanium oxides from Sahelian sources still detectable in Atlantic Ocean observations. The rapid changes in isotope chemistry found in AEROSE dust samples provide a unique marker of Saharan source regions and their relative contributions to desert outflows in the Atlantic. These elemental indicators provide source region apportionments of Sahara Desert aerosol flux and deposition into the Atlantic Ocean, as well as a basis for model and satellite validation of Saharan dust emissions for regional climate assessments.

Published

2024

28. Combined Characterization of Airborne Saharan Dust above Sofia, Bulgaria, during Blocking-Pattern Conditioned Dust Episode in February 2021.

Author

Peshev, Zahari, Chaikovsky, Anatoli, Evgenieva, Tsvetina, Pescherenkov, Vladislav, Vulkova, Liliya, Deleva, Atanaska, and Dreischuh, Tanja

Subjects

*DUST, *CLIMATE feedbacks, *REMOTE sensing

Abstract

The wintertime outbreaks of Saharan dust, increasing in intensity and frequency over the last decade, have become an important component of the global dust cycle and a challenging issue in elucidating its feedback to the ongoing climate change. For their adequate monitoring and characterization, systematic multi-instrument observations and multi-aspect analyses of the distribution and properties of desert aerosols are required, covering the full duration of dust events. In this paper, we present observations of Saharan dust in the atmosphere above Sofia, Bulgaria, during a strong dust episode over the whole of Europe in February 2021, conditioned by a persistent blocking weather pattern over the Mediterranean basin, providing clear skies and constant measurement conditions. This study was accomplished using different remote sensing (lidar, satellite, and radiometric), in situ (particle analyzing), and modeling/forecasting methods and resources, using real measurements and data (re)analysis. A wide range of columnar and range/time-resolved optical, microphysical, physical, topological, and dynamical characteristics of the detected aerosols dominated by desert dust are obtained and profiled with increased accuracy and reliability by combining the applied approaches and instruments in terms of complementarity, calibration, and normalization. Vertical profiles of the aerosol/dust total and mode volume concentrations are presented and analyzed using the LIRIC-2 inversion code joining lidar and sun-photometer data. The results show that interactive combining and use of various relevant approaches, instruments, and data have a significant synergistic effect and potential for verifying and improving theoretical models aimed at complete aerosol/dust characterization. [ABSTRACT FROM AUTHOR]

Published

2023

29. Approach into the influence of Saharan dust on the physicochemical properties of PM2.5 in Monterrey, México

Author

Martinez-Verduzco, R. O., Reyna-Gomez, L. M., Cruz-López, A., Carrillo-Avila, J. R., Valdez-Cavazos, A., and Suárez-Vázquez, S. I.

Published

2024

30. Dust Optical and Microphysical Properties of Saharan and Saudi Arabian Deserts Distributed in Europe Based on AERONET Data Products.

Author

Giannakaki, Elina, Verykiou, Eirini, Vasileiou, Eftychia, and Komppula, Mika

Subjects

DUST, LIDAR, CLIMATE change, DATA analysis

Abstract

This study investigates the spatial distribution of optical and microphysical dust properties in Europe and possible differences between the Saharan and Saudi Arabian deserts' dust particles based on the AERONET network. Data were collected within the period from 2001 to 2018 from 16 different stations. Pure dust conditions were identified. The Saudi Arabian lidar ratio (at 440 nm) was determined to be 53 ± 7 sr, much lower than the Saharan lidar ratio at the same wavelength, which was found to be 66 ± 10 sr. Particle depolarization ratio values at 440 nm were similar for both regions. Although our findings are consistent with earlier studies based on AERONET products, they do not agree with lidar observations. We found significantly larger lidar ratios at 440 nm both for Arabian dust (difference of 15 sr) and Saharan dust (difference of 13 sr) compared to lidar observations. These differences are smaller at 532 nm. Differences at both 440 and 532 nm between AERONET and lidar observations were on the order of 5 sr for Arabian dust and even smaller (order of 2 sr) for Saharan dust. [ABSTRACT FROM AUTHOR]

Published

2023

31. Air Quality and Health Impacts

Author

Kalivitis, Nikolaos, Papatheodorou, Stefania, Maesano, Cara Nichole, Annesi-Maesano, Isabella, Dulac, François, editor, Sauvage, Stéphane, editor, and Hamonou, Eric, editor

Published

2022

32. Impact of Atmospheric Deposition on Marine Chemistry and Biogeochemistry

Author

Guieu, Cécile, Ridame, Céline, Dulac, François, editor, Sauvage, Stéphane, editor, and Hamonou, Eric, editor

Published

2022

33. Aerosol Composition and Reactivity

Author

Becagli, Silvia, Dulac, François, editor, Sauvage, Stéphane, editor, and Hamonou, Eric, editor

Published

2022

34. Atmospheric Inputs and Biogeochemical Consequences in High-Mountain Lakes

Author

Reche, Isabel, Mladenov, Natalie, Pulido-Villena, Elvira, Morales-Baquero, Rafael, Zamora, Regino, editor, and Oliva, Marc, editor

Published

2022

35. Machine Learning-Based Improvement of Aerosol Optical Depth from CHIMERE Simulations Using MODIS Satellite Observations.

Author

Lemmouchi, Farouk, Cuesta, Juan, Lachatre, Mathieu, Brajard, Julien, Coman, Adriana, Beekmann, Matthias, and Derognat, Claude

Subjects

*MODIS (Spectroradiometer), *SUPERVISED learning, *AEROSOLS, *ARTIFICIAL neural networks, *BOOSTING algorithms, *CHEMICAL models, *ARTIFICIAL satellites

Abstract

We present a supervised machine learning (ML) approach to improve the accuracy of the regional horizontal distribution of the aerosol optical depth (AOD) simulated by the CHIMERE chemistry transport model over North Africa and the Arabian Peninsula using Moderate Resolution Imaging Spectroradiometer (MODIS) AOD satellite observations. Our method produces daily AOD maps with enhanced precision and full spatial domain coverage, which is particularly relevant for regions with a high aerosol abundance, such as the Sahara Desert, where there is a dramatic lack of ground-based measurements for validating chemistry transport simulations. We use satellite observations and some geophysical variables to train four popular regression models, namely multiple linear regression (MLR), random forests (RF), gradient boosting (XGB), and artificial neural networks (NN). We evaluate their performances against satellite and independent ground-based AOD observations. The results indicate that all models perform similarly, with RF exhibiting fewer spatial artifacts. While the regression slightly overcorrects extreme AODs, it remarkably reduces biases and absolute errors and significantly improves linear correlations with respect to the independent observations. We analyze a case study to illustrate the importance of the geophysical input variables and demonstrate the regional significance of some of them. [ABSTRACT FROM AUTHOR]

Published

2023

36. Influence of Saharan Dust on the Composition of Urban Aerosols in Palermo City (Italy)

Author

Daniela Varrica and Maria Grazia Alaimo

Subjects

Saharan dust, elemental ratios, Rare Earth Elements, Meteorology. Climatology, QC851-999

Abstract

The Mediterranean Basin is involved in a recurring phenomenon wherein air masses laden with dust from North Africa impact the southern regions of the European continent. Saharan dust has been associated with increased mortality and respiratory symptoms. Palermo is a large coastal city, and in addition to the impact of desert dust particles, it has a mixture of anthropogenic sources of pollutants. In this study, we collected Saharan dust samples during August 2022 and October 2023, following a high-intensity Saharan dust event, and measured concentrations of 33 major and trace elements as well as Rare Earth Elements (REE). The mineralogical characterization of the deposition dust collected during Saharan events revealed calcite, dolomite, quartz, and clay minerals. The presence of palygorskite is indicative of Saharan events. Seven elements (Ca, Mg, Al, Ti, Fe, K, and Na) account for 98% of the total analyzed inorganic burden. Elemental ratios are valuable tools in atmospheric sciences for estimating sources of air masses. The results highlight that the city of Palermo is mainly affected by dust from the north-western Sahara.

Published

2024

37. Microorganisms Isolated from Saharan Dust Intrusions in the Canary Islands and Processes of Mineral Atmospherogenesis

Author

Azahara Navarro, Ana del Moral, Irene de Pablos, Rafael Delgado, Jesús Párraga, Juan M. Martín-García, and Fernando Martínez-Checa

Subjects

extremophiles, Saharan dust, iberulite, atmospherogenesis, Canary Islands, calima, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Global warming due to climate change has increased the frequency of sand and dust storms that affect air quality and ecosystems in general, contributing to air pollution. The Sahara Desert is the most potent emitter of atmospheric dust. The atmosphere is an extreme environment and microorganisms living in the troposphere are exposed to greater ultraviolet radiation, desiccation, low temperatures and nutrient deprivation than in other habitats. The Iberian Peninsula, and specifically the Canary Islands—due to its strategic location—is one of the regions that receive more Saharan dust particles annually, increasing year after year, although culturable microorganisms had previously never been described. In the present work, dust samples were collected from three calima events in the Canary Islands between 2021 and 2022. The sizes, mineralogical compositions and chemical compositions of dust particles were determined by laser diffraction, X-ray diffraction (XRD) and X-ray photoelectron spectroscopy (XPS), respectively. Particle morphology and biological features were also studied by scanning electron microscopy (SEM-EDX) and confocal laser scanning microscopy (CLSM). The mineral–bacteria interactions were described from microscopic observations, which revealed the presence of iberulites and small neoformed kaolinite crystals in association with bacteria. This article defines the term “mineral atmospherogenesis” and its variant, “mineral bioatmospherogenesis”, through microbial interaction. This is the first described case of kaolinite produced through mineral bioatmospherogenesis. The bacterial growth in atmospheric dust was illustrated in SEM images, constituting a novel finding. Twenty-three culturable microorganisms were isolated and identified by 16S rRNA sequencing. Members of the phyla Pseudomonadota, Bacillota and Actinomycetota have been found. Some of these microorganisms, such as Peribacillus frigoritolerans, have Plant Growth-Promoting Rhizobacteria (PGPR) properties. Potential human pathogenic bacteria such as Acinetobacter lwoffii were also found. The presence of desert dust and iberulites in the Canary Islands, together with transported biological components such as bacteria, could have a significant impact on the ecosystem and human health.

Published

2024

38. Temporal Relationships Between Saharan Dust Proxies, Climate, and Meningitis in Senegal.

Author

Yarber, Aara'L. Y., Jenkins, Gregory S., Singh, Ajit, and Diokhane, Aminata

Subjects

MIDDLE-income countries, MENINGITIS, DUST, BACTERIAL meningitis, PARTICULATE matter, TRADE winds

Abstract

The Harmattan, a dry, northeasterly trade wind, transports large quantities of Saharan dust over the Sahelian region during the dry season (December–March). Studies have shown that bacterial meningitis outbreaks in Sahelian regions show hyper‐endemic to endemic levels during high‐dust months. We examine the (a) seasonality and intraseasonal variability of dust, climate, and meningitis and the (b) quantitative relationships between various dust proxies with meningitis lags of 0–10 weeks in Senegal from 2012 to 2017. The results show that the onset of the meningitis season occurs in February, roughly 2 months after the dusty season has begun. The meningitis season peaks at the beginning of April, when northeasterly wind speeds and particulate matter (PM) are relatively high, and the meningitis season ends near the end of June, when temperature and humidity rise and northeasterly wind speeds decline. Furthermore, we find that Senegal's relatively high humidity year‐round may help slow the transmission of the infection, contributing to a lower disease incidence than landlocked countries in the meningitis belt. Lastly, our results suggest the desert dust may have a significant impact on the onset to the peak of the meningitis season in Senegal, particularly at the 0–2 and 10‐week lag, whether that be directly through biological processes or indirectly through changes in human behavior. PM and visibility, however, are not in phase with aerosol optical depth throughout the year and consequently show different relationships with meningitis. This study further exemplifies the critical need for more PM, meteorological, and meningitis measurements in West Africa to further resolve these relationships. Plain Language Summary: The World Health Organization has estimated that 7 million people are killed from air pollution every year, with low and middle‐income countries having the highest exposure. West Africa is particularly vulnerable to elevated particulate matter (PM) emissions from Saharan dust intrusions during the dry season (December–March), which have been shown to cause cardiovascular and respiratory disease. We examine the relationship between climate, Saharan dust, and meningitis cases in Senegal from 2012 to 2017 using various dust proxies. We find that the onset of the disease occurs in February, roughly 2 months after the dusty season has begun. The disease peaks during the dry season when northeasterly wind speeds and PM are relatively high and declines as the temperature and humidity increase. We find that PM and visibility are not in phase with aerosol optical depth and thus, have different relationships with meningitis throughout the meningitis season. However, we suspect dust may have a significant effect on the upstart and peak of the meningitis season, whether that be biologically or through changes in human behavior. Lastly, relatively high humidity in Senegal year‐round may favor fewer meningitis cases compared to landlocked countries in the meningitis belt. Key Points: Senegal's relatively high humidity year‐round may favor relatively low meningitis incidenceMeningitis seasonality may be influenced by dust, Harmattan wind, temperature, and humiditySaharan dust may affect the onset of the meningitis season through direct or indirect processes [ABSTRACT FROM AUTHOR]

Published

2023

39. Constant and fluctuating high temperatures interact with Saharan dust leading to contrasting effects on aquatic microbes over time.

Author

Vila Duplá, María, Villar-Argaiz, Manuel, Medina-Sánchez, Juan Manuel, González-Olalla, Juan Manuel, and Carrillo, Presentación

Published

2024

40. Dust Optical and Microphysical Properties of Saharan and Saudi Arabian Deserts Distributed in Europe Based on AERONET Data Products

Author

Elina Giannakaki, Eirini Verykiou, Eftychia Vasileiou, and Mika Komppula

Subjects

desert dust particles, lidar ratio, depolarization ratio, Saharan dust, Saudi Arabian dust, Environmental sciences, GE1-350

Abstract

This study investigates the spatial distribution of optical and microphysical dust properties in Europe and possible differences between the Saharan and Saudi Arabian deserts’ dust particles based on the AERONET network. Data were collected within the period from 2001 to 2018 from 16 different stations. Pure dust conditions were identified. The Saudi Arabian lidar ratio (at 440 nm) was determined to be 53 ± 7 sr, much lower than the Saharan lidar ratio at the same wavelength, which was found to be 66 ± 10 sr. Particle depolarization ratio values at 440 nm were similar for both regions. Although our findings are consistent with earlier studies based on AERONET products, they do not agree with lidar observations. We found significantly larger lidar ratios at 440 nm both for Arabian dust (difference of 15 sr) and Saharan dust (difference of 13 sr) compared to lidar observations. These differences are smaller at 532 nm. Differences at both 440 and 532 nm between AERONET and lidar observations were on the order of 5 sr for Arabian dust and even smaller (order of 2 sr) for Saharan dust.

Published

2023

41. Evaluation of African Dust Events and Effect on PM10 Concentration in Tunisia

Author

Bouchlaghem, Karim, Chtioui, Houda, Gazzah, Mohamed Hichem, Förstner, Ulrich, Series Editor, Rulkens, Wim H., Series Editor, Salomons, Wim, Series Editor, Ksibi, Mohamed, editor, Ghorbal, Achraf, editor, Chakraborty, Sudip, editor, Chaminé, Helder I., editor, Barbieri, Maurizio, editor, Guerriero, Giulia, editor, Hentati, Olfa, editor, Negm, Abdelazim, editor, Lehmann, Anthony, editor, Römbke, Jörg, editor, Costa Duarte, Armando, editor, Xoplaki, Elena, editor, Khélifi, Nabil, editor, Colinet, Gilles, editor, Miguel Dias, João, editor, Gargouri, Imed, editor, Van Hullebusch, Eric D., editor, Sánchez Cabrero, Benigno, editor, Ferlisi, Settimio, editor, Tizaoui, Chedly, editor, Kallel, Amjad, editor, Rtimi, Sami, editor, Panda, Sandeep, editor, Michaud, Philippe, editor, Sahu, Jaya Narayana, editor, Seffen, Mongi, editor, and Naddeo, Vincenzo, editor

Published

2021

42. Precipitation Chemistry in Bulgaria During Saharan Dust Outbreaks

Author

Georgieva, Emilia, Hristova, Elena, Veleva, Blagorodka, Kacprzyk, Janusz, Series Editor, Dobrinkova, Nina, editor, and Gadzhev, Georgi, editor

Published

2021

43. Atmospheric Deposition Over the Caribbean Region: Sea Salt and Saharan Dust Are Sources of Essential Elements on the Island of Guadeloupe.

Author

Xu‐Yang, Yangjunjie, Dessert, Céline, and Losno, Rémi

Subjects

ATMOSPHERIC deposition, SEA salt, ATMOSPHERIC nitrogen, SEA surface microlayer, DUST, NUCLEOSYNTHESIS, TRADE winds

Abstract

Dust emitted from North Africa is transported over long distances and has a strong impact on large areas over the North Tropical Atlantic Ocean. Sea salt emitted by the sea surface is the second source of essential elements transported in the atmosphere and plays a major role in the cycles of alkaline‐earth metals in the ecosystems of tropical North Atlantic Islands. The total atmospheric deposition fluxes were continuously sampled on a weekly basis in Guadeloupe, Lesser Antilles, from March 2015 to August 2018 (41 months). Elemental deposition fluxes, including Al, Ca, K, Mg, Fe, Na, P, S, and Zn, were measured for all samples to provide the first long time series of atmospheric elemental deposition fluxes over the Lesser Antilles region. It is shown that: (a) the three sources of atmospheric deposits in Guadeloupe for the presented elements are sea salt (for K, Ca, Mg, Na, and S), long‐range transported Saharan dust (for Al, Ca, K, and Fe), and biogenic particles (for P and Zn); (b) the average deposition mass fluxes of sea salt and Saharan dust are 17.4 and 11.2 g.m−2.year−1, respectively, without noticeable inter‐annual variations; (c) a pronounced seasonality is found for the Saharan dust deposition, for which maximum flux values are observed between June and July each year and 85% of the annual deposition flux occurs between April and September; (d) the deposition flux of sea salt is strongly correlated to local wind speed, without seasonality. Plain Language Summary: Saharan dust and sea salt contribute toward feeding trees living on Caribbean Island ground with alkaline, alkaline‐earth cations and other important elements. Saharan dust is transported time to time from North Africa with a higher frequency of events in summer. Sea salt is continuously locally emitted from the sea surface by the action of trade winds and storms on the sea surface that produces sea water brine. For the first time, we have measured the Saharan dust and sea salt deposition flux continuously for 3 years in Guadeloupe. We have found that Saharan dust brings iron, calcium, and potassium, and sea salt brings sodium, magnesium, sulfur, and potassium. The high flux of phosphorus is due to the local recycling of living debris and zinc which probably come from sea surface micro‐layer torn by the wind. These results enhance our knowledge of nutrients cycles in the North Atlantic region. Key Points: We have monitored atmospheric deposition in Guadeloupe over a 3‐year period with measurements of Al, Na, Mg, P, S, K, Ca, Fe, and ZnStrong seasonality for Saharan dust, no inter‐annual deposition flux variations for both sea salt and Saharan dustWe suggest that the contributions of Saharan dust, sea salt, and biogenic emissions explain the origin of the deposited elements [ABSTRACT FROM AUTHOR]

Published

2022

44. Temporal variation of surface O3, NOx and PM10 and associated human health risk in Gabès suburban (South-Eastern Tunisia): multi-scales impact of sources and meteorology.

Author

Ahbil, Khaoula, Sellami, Fatma, and Azri, Chafai

Abstract

Abstract The study of daily and hourly average concentrations variability of surface O3, NO, NO2 and PM10 was carried out at the proximity of a crossroad (≈23,000 vehicles per day) located in suburban Gabès, Tunisia. It was performed during 2017–2019 “winter/spring” seasonal transitions and spring seasons. Depending on multi-scale sources and meteorology, it showed variable values ​​within each studied annual period and the years. Statistical approaches based on factorial analysis of correspondences (FAC) and principal component analysis (PCA) revealed three main components of pollution; local retraced by NOx, regional by O3 and synoptic by PM10. Furthermore, they have refined the significant impacts of Saharan dust advections on high recorded PM10 and NOx (by drained urban plume) and of both deep depressions (cut-off lows) and Azores anticyclonic events on the excess of surface O3 concentrations. The investigation of the air quality health index (AQHI) related to the selected pollutants highlighted the significant effect of PM10. It has revealed that more than 53% of the total days were retraced by a moderate air quality index level linked to the negative impact of PM10. Besides, for such a pollutant, more than 20% of the total days were unhealthy for sensitive groups. Even for ordinary people, almost 3% of the total days were shown to be very unhealthy to hazardous. [ABSTRACT FROM AUTHOR]

Published

2022

45. Simultaneous Monitoring of Outdoor PAHs and Particles in a French Peri-Urban Site during COVID Restrictions and the Winter Saharan Dust Event.

Author

Nursanto, Farhan Ramadzan, Vaz-Ramos, Joana, Delhomme, Olivier, Bégin-Colin, Sylvie, and Le Calvé, Stéphane

Subjects

*DUST, *COVID-19, *PARTICULATE matter, *FRENCH language, *MINERAL dusts, *POLYCYCLIC aromatic hydrocarbons, *DUST storms, *POLLUTANTS

Abstract

The presence of polycyclic aromatic hydrocarbons (PAHs) and particulate matter (PM) in air is known to provoke deleterious effects on human health. This work focused on the monitoring of PM and PAHs in the air over four weeks in a peri-urban site in Strasbourg (France), using a three-stage cascade impactor and a particle analyser allowing PM1, PM2.5 and PM10 discrimination. Meteorological conditions were monitored to study their influence on the pollutant levels. The average PM10 concentration of the cascade impactor and particle analyser varied from 11.8 to 80.2 µg/m3 and 10.6 to 220.2 µg/m3, respectively. The PAH total concentration ranged in 1.1–7.6 ng/m3 and a predominance of 5- and 6-ring PAHs was observed. PAHs were also more abundant in finer particles (PM1). Specifically, identified PAHs are traffic tracers suggesting that vehicular emission was one of its main sources. Two pollution episodes, associated with either a Saharan dust wind episode or traffic pollution, were observed, and led to PM10 and PM2.5 surpassing the daily limit values established by the European Union despite the traffic limitations according to the COVID restrictions. The total PAH concentrations were the highest during these periods suggesting PAHs might be bound to and transported via dust particles. [ABSTRACT FROM AUTHOR]

Published

2022

46. Saharan dust and respiratory health: Understanding the link between airborne particulate matter and chronic lung diseases (Review).

Author

Georgakopoulou VE, Taskou C, Diamanti A, Beka D, Papalexis P, Trakas N, and Spandidos DA

Abstract

Saharan dust storms, which originate from the Sahara desert, have a significant impact on global health, especially on respiratory conditions of populations exposed to fine particulate matter that travels across continents. Dust events, characterized by the transport of mineral dust such as quartz and feldspar, lead to the suspension of particulate matter in the atmosphere, capable of traversing long distances and affecting air quality adversely. Emerging research links these dust episodes with increased incidence and exacerbation of lung diseases, including asthma and chronic obstructive pulmonary disease, especially during peak dust emission seasons from November to March. The present review aims to synthesize existing scientific evidence concerning the respiratory health impacts of Saharan dust, examining the environmental dynamics of dust transmission, the physical and chemical properties of dust particles, and their biological effects on human health. Further, it assesses epidemiological studies and discusses public health strategies for mitigating adverse health outcomes. Given the complexity of interactions between atmospheric dust particles and respiratory health, this review also highlights critical research gaps that need attention to better understand and manage the health risks associated with Saharan dust., Competing Interests: DAS is the Editor-in-Chief for the journal, but had no personal involvement in the reviewing process, or any influence in terms of adjudicating on the final decision, for this article. The other authors confirm that they have no competing interests., (Copyright: © 2024 Georgakopoulou et al.)

Published

2024

47. Combined Characterization of Airborne Saharan Dust above Sofia, Bulgaria, during Blocking-Pattern Conditioned Dust Episode in February 2021

Author

Zahari Peshev, Anatoli Chaikovsky, Tsvetina Evgenieva, Vladislav Pescherenkov, Liliya Vulkova, Atanaska Deleva, and Tanja Dreischuh

Subjects

atmospheric aerosols, aerosol properties, Saharan dust, dust concentration, lidar, sun photometer, Science

Abstract

The wintertime outbreaks of Saharan dust, increasing in intensity and frequency over the last decade, have become an important component of the global dust cycle and a challenging issue in elucidating its feedback to the ongoing climate change. For their adequate monitoring and characterization, systematic multi-instrument observations and multi-aspect analyses of the distribution and properties of desert aerosols are required, covering the full duration of dust events. In this paper, we present observations of Saharan dust in the atmosphere above Sofia, Bulgaria, during a strong dust episode over the whole of Europe in February 2021, conditioned by a persistent blocking weather pattern over the Mediterranean basin, providing clear skies and constant measurement conditions. This study was accomplished using different remote sensing (lidar, satellite, and radiometric), in situ (particle analyzing), and modeling/forecasting methods and resources, using real measurements and data (re)analysis. A wide range of columnar and range/time-resolved optical, microphysical, physical, topological, and dynamical characteristics of the detected aerosols dominated by desert dust are obtained and profiled with increased accuracy and reliability by combining the applied approaches and instruments in terms of complementarity, calibration, and normalization. Vertical profiles of the aerosol/dust total and mode volume concentrations are presented and analyzed using the LIRIC-2 inversion code joining lidar and sun-photometer data. The results show that interactive combining and use of various relevant approaches, instruments, and data have a significant synergistic effect and potential for verifying and improving theoretical models aimed at complete aerosol/dust characterization.

Published

2023

48. First Ever Observations of Mineral Dust in Wintertime over Warsaw, Poland.

Author

Szczepanik, Dominika M., Ortiz-Amezcua, Pablo, Heese, Birgit, D'Amico, Giuseppe, and Stachlewska, Iwona S.

Subjects

*MINERAL dusts, *WINTER, *DUST, *TEMPERATE climate, *AIR masses, *AEROSOLS, TROPICAL climate

Abstract

The long-range transport of desert dust over the area of the temperate climate zone is associated with the influx of hot air masses due to the location of the sources of this aerosol in the tropical climate zone. Between 24–26 February 2021, such an aerosol outbreak took place and reached Central Europe. The mean temperature of +11.7 °C was recorded during the event. A comparison of this value to the 20-year (2000–2020) average February temperature for Warsaw (−0.2 °C) indicates the uniqueness of the meteorological conditions. It was the first wintertime inflow of Saharan dust over Warsaw, the presence of which was confirmed by lidar and sun-photometer measurements. The properties of the desert dust layers were obtained; the mean values of the particle depolarization for the fully developed mineral dust layer were 13 ± 3% and 22 ± 4% for 355 and 532 nm, respectively. The aerosol optical thickness was high with average values >0.36 for all wavelengths smaller than 500 nm. The three-modal, aerosol size distribution was dominated by coarse-mode particles, with a visible contribution of accumulation-mode particles. It suggests the possible presence of other aerosol types. [ABSTRACT FROM AUTHOR]

Published

2022

49. Chemical characterisation of natural and anthropogenic inputs of dust in the seasonal snowpack (2017–2020) at Calderone Glacier (Gran Sasso d'Italia).

Author

Bruschi, Federica, Moroni, Beatrice, Petroselli, Chiara, Gravina, Paola, Selvaggi, Roberta, Pecci, Massimo, Spolaor, Andrea, Tuccella, Paolo, Raparelli, Edoardo, Gabrieli, Jacopo, Esposito, Giulio, D'Aquila, Pinuccio, and Cappelletti, David

Subjects

ATMOSPHERIC aerosols, GLACIERS, SEASONS, AIR masses, DUST, ION exchange chromatography, CARBONACEOUS aerosols, MINERAL dusts

Abstract

Environmental context: We present a chemical characterisation of the seasonal snowpack sampled for four consecutive years at the Calderone, the southernmost glacier still surviving in peninsular Italy. This debris covered glacier recently split into two little ice bodies, whose evolution could be influenced by the snowpack properties. In particular the impact of long-range aerosol advections on concentrations of impurities in the snowpack over the local background is discussed. Rationale: The Calderone Glacier (Central Apennine, Gran Sasso d'Italia mountain group) is the southernmost glacial apparatus in Europe, split into two glacierets (Upper and Lower Calderone) since the end of the last millennium. Because of its location and altitude, this site is mainly characterised by the long-range transport of air masses which arise from different Mediterranean source regions. Therefore, the seasonal snowpack's chemistry is strongly affected by the dry and wet deposition of contaminants associated with anthropogenic and natural sources. Methodology: In the present study, the seasonal snowpack stratified on the Calderone glacier has been characterised for four consecutive years (2017–2020) in the same monitoring site (2700 m asl), where a snow pit has been dug yearly, to observe the modification of chemical and physical properties depending on local and long-range atmospheric contributions. We determined the concentrations and fluxes of major inorganic ions (MIs) by ion chromatography and of 31 trace elements (TEs) by triple quadrupole ICP-MS. Results: Major and trace element concentration profiles along the snowpack allowed to discriminate the snow layers contaminated by long range advections from the uncontaminated ones. The uncontaminated snow layers' concentrations were used to calculate regional background values. The results have been compared to other remote sites to assess their robustness. Discussion: Different source contributions have been recognised using enrichment factors for the trace elements, particularly crustal, marine and anthropogenic. Deposited atmospheric aerosols, found in the snowpack as distinct layers generated during intense air mass advections, have been correlated to these contributions. Environmental context. We present a chemical characterisation of the seasonal snowpack sampled for four consecutive years at the Calderone, the southernmost glacier still surviving in peninsular Italy. This debris covered glacier recently split into two little ice bodies, whose evolution could be influenced by the snowpack properties. In particular the impact of long-range aerosol advections on concentrations of impurities in the snowpack over the local background is discussed. [ABSTRACT FROM AUTHOR]

Published

2022

50. Large-Scale Saharan Dust Episode in April 2019: Study of Desert Aerosol Loads over Sofia, Bulgaria, Using Remote Sensing, In Situ, and Modeling Resources.

Author

Peshev, Zahari, Deleva, Atanaska, Vulkova, Liliya, and Dreischuh, Tanja

Subjects

*MINERAL dusts, *REMOTE sensing, *AEROSOLS, *DUST, *CLIMATE change, *AIR masses, *REMOTE-sensing images

Abstract

Emissions of immense amounts of desert dust into the atmosphere, spreading over vast geographical areas, are in direct feedback relation with ongoing global climate changes. An extreme large-scale Saharan dust episode occurred over Mediterranean and Europe in April 2019, driven by a dynamic blocking synoptic pattern (omega block) creating conditions for a powerful northeastward circulation of air masses rich in dust and moisture. Here, we study and characterize the effects of related dust intrusion over Sofia, Bulgaria, using lidar remote sensing combined with in situ measurements, satellite imagery, and modeling data. Optical and microphysical parameters of the desert aerosols were obtained and vertically profiled, namely, backscatter coefficients and backscatter-related Ångström exponents, as well as statistical distributions of the latter as qualitative analogs of the actual particle size distributions. Dynamical and topological features of the dust-dominated aerosol layers were determined. Height profiles of the aerosol/dust mass concentration were obtained by synergistic combining and calibrating lidar and in situ data. The comparison of the retrieved mass concentration profiles with the dust modeling ones shows a satisfactory compliance. The local meteorological conditions and the aerosol composition and structure of the troposphere above Sofia during the dust event were seriously affected by the desert air masses. [ABSTRACT FROM AUTHOR]

Published

2022